Volume 254, 2024

Fast and accurate nonadiabatic molecular dynamics enabled through variational interpolation of correlated electron wavefunctions

Abstract

We build on the concept of eigenvector continuation to develop an efficient multi-state method for the rigorous and smooth interpolation of a small training set of many-body wavefunctions through chemical space at mean-field cost. The inferred states are represented as variationally optimal linear combinations of the training states transferred between the many-body bases of different nuclear geometries. We show that analytic multi-state forces and nonadiabatic couplings from the model enable application to nonadiabatic molecular dynamics, developing an active learning scheme to ensure a compact and systematically improvable training set. This culminates in application to the nonadiabatic molecular dynamics of a photoexcited 28-atom hydrogen chain, with surprising complexity in the resulting nuclear motion. With just 22 DMRG calculations of training states from the low-energy correlated electronic structure at different geometries, we infer the multi-state energies, forces and nonadiabatic coupling vectors at 12 000 geometries with provable convergence to high accuracy along an ensemble of molecular trajectories, which would not be feasible with a brute force approach. This opens up a route to bridge the timescales between accurate single-point correlated electronic structure methods and timescales of relevance for photo-induced molecular dynamics.

Graphical abstract: Fast and accurate nonadiabatic molecular dynamics enabled through variational interpolation of correlated electron wavefunctions

Associated articles

Supplementary files

Article information

Article type
Paper
Submitted
17 3 2024
Accepted
02 5 2024
First published
02 5 2024
This article is Open Access
Creative Commons BY license

Faraday Discuss., 2024,254, 542-569

Fast and accurate nonadiabatic molecular dynamics enabled through variational interpolation of correlated electron wavefunctions

K. Atalar, Y. Rath, R. Crespo-Otero and G. H. Booth, Faraday Discuss., 2024, 254, 542 DOI: 10.1039/D4FD00062E

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